Performances are enhanced and improved tremendously for existing USB connectors with new improvised fiber-optical connection features and their capabilities. Existing USB connectors, such as user-friendly reversible Type-A and USB Type-C connectors are modified, improvised and retrofitted using means of allocating unused spaces and surfaces to allow fiber-optical wires and connections inside the user-friendly reversible Type-A and USB Type-C connectors. This modification will not affect the regular functions and performances of the user-friendly reversible Type-A and USB Type-C connections. New fiber-optical connections will enhance and improve reversible Type A and USB Type-C as compared to regular user-friendly reversible Type-A and Type-C connectors that have only copper wire connections. They are faster in speed, with the capability of much more bandwidth, longer transmission distance, lighter weight, water proof with corrosion resistance, better data security, immunity to electro-magnetic interference (EMI) and generating no EMI noise, lower cost, less wear and tear for longer life, better safety with non-conductive connectors, and much more.

Performances are enhanced and improved tremendously for existing USB connectors with new improvised fiber-optical connection features and their capabilities. Existing USB connectors, such as user-friendly reversible Type-A and USB Type-C connectors are modified, improvised and retrofitted using means of allocating unused spaces and surfaces to allow fiber-optical wires and connections inside the user-friendly reversible Type-A and USB Type-C connectors. This modification will not affect the regular functions and performances of the user-friendly reversible Type-A and USB Type-C connections. New fiber-optical connections will enhance and improve reversible Type A and USB Type-C as compared to regular user-friendly reversible Type-A and Type-C connectors that have only copper wire connections. They are faster in speed, with the capability of much more bandwidth, longer transmission distance, lighter weight, water proof with corrosion resistance, better data security, immunity to electro-magnetic interference (EMI) and generating no EMI noise, lower cost, less wear and tear for longer life, better safety with non-conductive connectors, and much more.

A communication connector has an outer housing with an opening, a shielding wrap at least partially enclosing the outer housing, and a contact carrier assembly configured to be interested into the opening of the outer housing. The contact carrier assembly at least partially encloses at least two contacts each with an insulation displacement contact (IDC). The contact carrier assembly also has an integrated wire cap that utilizes a hinge feature to press cable conductors of a cable into their respective IDCs.

A communication connector has an outer housing with an opening, a shielding wrap at least partially enclosing the outer housing, and a contact carrier assembly configured to be interested into the opening of the outer housing. The contact carrier assembly at least partially encloses at least two contacts each with an insulation displacement contact (IDC). The contact carrier assembly also has an integrated wire cap that utilizes a hinge feature to press cable conductors of a cable into their respective IDCs.

An electrical connector assembly includes a plug connector, a cable electrically connecting to the plug connector, an outer cover enclosing the plug connector and the cable, a pair of latches mounted to the plug connector, and a pair of buttons mounted to the outer cover for operating the pair of latches, wherein each of the pair of latches includes a spring arm, a securing portion at an inner side of the spring arm, and a pressing portion at an outer side of the spring arm, and each of the pair of buttons includes a pivot at one end thereof, a stopper at an opposite end thereof, and an abutting portion coupled to the pressing portion.

In one embodiment, an apparatus includes a connector plug for attachment to a single pair Ethernet cable comprising a pair of conductors, and configured for being received in a connector receptacle. The connector plug includes a first end for receiving the single pair Ethernet cable and a second end having a pair of contacts, each of the contacts comprising a receptacle contact interface, a conductor interface, and an extension to provide an increased width between conductor gripping prongs at the conductor interface while maintaining a consistent spacing between the pair of contacts at the receptacle contact interface with connector plugs configured to mate with different gauge cables. The connector plug comprises a latch for secure attachment to the receptacle and a pull cord connected to the latch and accessible when the connector plug is inserted into the receptacle with other connector plugs for release of the connector plug.

In one embodiment, an apparatus includes a connector plug for attachment to a single pair Ethernet cable comprising a pair of conductors, and configured for being received in a connector receptacle. The connector plug includes a first end for receiving the single pair Ethernet cable and a second end having a pair of contacts, each of the contacts comprising a receptacle contact interface, a conductor interface, and an extension to provide an increased width between conductor gripping prongs at the conductor interface while maintaining a consistent spacing between the pair of contacts at the receptacle contact interface with connector plugs configured to mate with different gauge cables. The connector plug comprises a latch for secure attachment to the receptacle and a pull cord connected to the latch and accessible when the connector plug is inserted into the receptacle with other connector plugs for release of the connector plug.

A telecommunications jack adapter for receiving multiple types of jacks can include an opening structure having a main body defining a central opening for receiving a first jack type having a first dimension and a second jack type having a second dimension greater than the first dimension, wherein the main body is flexible such that the opening structure matches the first dimension in a relaxed state and matches the second dimension in an expanded state. In some examples, the main body has deflectable latch members configured to engage with an opening structure configured to receive a third jack type.

A method of extending the usable length of a power-over-ethernet cable includes the steps of providing twisted pairs of wires with the conductor of each wire being a 20 AWG or 22 AWG conductor and terminating the cable at an RJ-45 style connector. The connector for the 20 AWG conductors has an insert therein with holes that can accommodate 20 AWG conductors. FEP, PVC or PP insulation may surround each conductor.

An arc prevention system including a jack having a receptacle, with the receptacle having an upper wall, a bottom wall, two opposing side walls and a back wall between the two opposing side walls, a sensor unit positioned on the back wall of the receptacle, where the sensor unit is positioned on the back wall of the receptacle such that the sensor unit engages a plug inserted into the receptacle.